Scalable electronics, computer, router, process control and other module/enclosures employing approximated tesselation(s)/tiling(s) or electronics and other modules from tow modules to columns, rows and arrays with optional deployment utilizing palletization for build out of existing industrial space and/or new construction with nestable wiring applicable from module and assembly level to molecular and atomic levels

ABSTRACT

Scalable Electronics, Computer, Router, Process Control and other Module/Enclosures Employing Approximated Tessellation/Tiling or Electronics and Other Modules from Two Modules to Columns, Rows and Arrays with Optional Deployment utilizing Palletization for Build out of Existing Industrial Space And/or New Construction with nestable wiring applicable from module and assembly and chip level to molecular and atomic levels.

The problems the invention solves are applicable to router, server process control and other machine farms and/or network-based implementations and network based computer architectures including wiring for chips and other artifices for electronic, optic and other processing as follows:

1. Battle hardening. [dynamic multi-module and/or nested modules with fail-over.]

2. Near universal standardized form factors for macroscopic packaging in which space is of cost and its conservation is of economic benefit.

3. Supercomputing and technology dependent high interconnect speeds.

4. Optimized industrial or military floor and volumetric space as measured by cost per area or volume.

5. New building construction and old building build out optimization for router farms, server farms, other network-based implementations and general machine farms.

6. Allows manual and/or electromechanical and/or automated individual [sub-]module access in one, two or three dimensional [sub-]tiered stacks and/or arrays with or without nesting for service including internal and external [re-]wiring, repair or replacement of inter-/intra-module communications interconnects and (sub-) modules with or without nesting, whereby such packaging may be manipulated for placement either manually or electro-mechanically.

7. Provides multiple thermal management options to minimize heat dissipation impact on module density.

8. To provide a near universal design platform for black-box/object based modular and nested/compartmentalized design and storage allowing economic trade-offs between battle hardening and green design.

9. Extended depth module and array stacking.

10. Hot swap.

11. Radiation containment, absorption and directionality/gain for approximated tessellations/tilings with sliding fit keyed or un-keyed radiation guides.

12. Geometry and/or wiring scalable from the module, assembly and chip level to the molecular and atomic levels.

The invention solves the above problems as follows:

1. Battle hardening, pending component selection, utilizing both inter- and/or intra- multi-module and nested inter- and/or intra-multi-module redundancy and wiring for fail-over and re-routing wiring with bypass based on approximated tessellation/tiling geometries with a sliding fit and with or without retractable interconnects and with or without quick-disconnects. Reference patent two incorporated herein by reference.

2. The invention provides near universal standardized form factors for macroscopic packaging by employing approximated tessellations/tilings. Module scale, layout and nesting are dictated by components including retractable interconnects with or without quick disconnects, bezels, patch panels, backing and mounting plates and pc boards with external side wall wire and cable guides and end cap interconnection baskets and covers. These features, conjunct [sub-] module hull to [sub-] module hull sliding fit and combined with suspension cabling, cable grippers and support hardware and guides make the system.

3. The invention provides integration/migration from a single module to massively parallel router, server, supercomputer or other technology based machine/process and super-computing/server/router farms. This is accomplished by enhancing command, data, and/or process and/or sensor communication by minimizing and standardizing path lengths for these functions within and without [sub-] module to [sub-] module vertice to vertice, flat to flat and end cap to end cap overall lengths and inter-module sliding-fit interconnect lengths. Examples in this environment include module and nested module active and passive hydraulic, fluidic, electrical, optical, nanotech and quantum components and their associated mechanical, electrical, optical, wave or particle propagation lengths, impedances and capacitances with associated circuitry, which dictate absolute circuit speeds. Fiber optics has similar limits, which may be boiled down to media propagation speed. Separately, hoses and other materials process-supply mechanisms will be similarly limited by speeds, feed rates and flow rates. The same is true for all analog or digital data transfer, and their DAC, ADC, transducers and their support circuitry.

4. For human touch and FCC compliance, the module hull, end basket cover, and handle are internally and/or externally coated or infused with EM and/or RF conductive and/or insulative material or shielding, with or without reinforcing frequency dependent mesh(-es) as necessary or for Tempest and anti-EMP applications. This is also done where wave-guides are formed by sliding-fit inter-module hull interfaces. Frequency appropriate absorptive and/or anti-reflective coatings are used beyond the delineated edges of open wave-guide and/or optical light guides with coatings for the operative radiation being used as part of the external hull.

5. The approximated hexagon shape is assumed herein as follows by way of example. The preferred embodiments are processor pipeline, stream and/or cluster-centric regarding communication channels as represented at the pallet level and/or any other multi-module “center of mass”. Accordingly, single modules [for non-polling systems] and three module sets [for polling systems] on center lines corresponding to the six (6) directions of the x-y-z planes and their corresponding diagonals and/or the hexagonal functional equivalent, six (6) directions per horizontal plane [(truncated) apex (6) and/or side centered diagonals (6)] derive said “center of mass” for a possible total of 12. Separately each vertical cross-section, again by apex (6) or flat side wall (6) allows for eight (8) directions and the associated wiring, cabling, etc. interconnects, axially [top-bottom], side to side [left right], diagonally [top left, bottom right] and last diagonally [bottom left, top right]. The concept is also incorporated by reference to the other submitted patent for those shape delineated elsewhere which include the standard regular or irregular tessellation/tilings as the as approximated with or without the dumbbell modifications. [An irregular tessellation/tiling is defined herein as an assymetrical tessellation/tiling as when the wiring at the edges of a column, row or array or attendant patch panels or other external or internal intra-module level interstitial support structure is not symmetrical by connection or by geometry.

6. Connection lengths in particular module directions, be they vertical or horizontal axes or diagonals are set equal by frequency, wavelength, impedance isotropically for all [stopped here] particular direction whereby parallel modules for a particular direction embody parallel processors for alternate logic trees and or polling, pending centering as indicated above. In these constructs, each direction corresponds to a critical time delay path for any form of circuitry, bus, communications protocol or process between modules and/or clusters regardless of technology. Examples include technology based on RC and RLC time constants, phase-locked loops, optical loops, parametrons, etc. The system employs delay line signal conditioning and/or optics to equalize and electrical lengths and delays as necessary for all directions.

7. The invention's near universal form factor utilizes approximated tessellation/tiling with a sliding fit and vertical bulkhead. Wire, wave, optical and radiation guides conjunct quick disconnects to approximate maximum co-planar surface area coverage which is extended into the third dimension by extruding the 2D [sub-]modules basic footprint into the third dimension thus forming the [sub-]module's 3D form-factor. In this way the (sub-)]modules optimize industrial or military floor space or volume and hence internal rate of return (IRR) for project comparison by hurdle rates as measured by square area projected volumetrically into the third dimension less a tolerance for the sliding fit] thus lowering costs while maintaining service access for equipment. Accordingly, designs are judged by comparative layout efficiency of equipment utilization by hurdle rates as applied, and realized in one, two or three-dimensional arrays.

8. The invention uses standard heavy duty industrial warehouse style shelving with a multilevel mezzanine option above the first floor. This allows for the build out of pre-existing industrial warehouse and other space to realize scalable integration/migration from a single unit to a router, server and supercomputer machine farms incorporating high-density multilevel facilities interconnected as required by catwalks and corridors. This utilizes cheaper industrial warehouse space for machine farms. In this embodiment, due to the portable nature of the shelving with or without multilevel mezzanine enhancements, pending implementation details, the build out itself may be portable, and therefore allows the possibility of site movement, pending more favorable lease, rent or other financial opportunities, including lower tax rates, as given under various governmental programs and negotiations, including between states.

9. The invention expands this technique to include standard building practices by adding standard external wall and roofing systems available for said mezzanine style shelving systems for new construction of buildings to purpose, utilizing palletization techniques and approximated tessellation/tiled enclosures described and incorporated by reference by the other provisional patent most closely submitted in time. In this way, new building construction is optimized as the shelving supports do double duty as ceiling and wall supports.

10. Service access to individual modules in stacks and arrays are aided by groupings based on pallets equipped with pallet dollies to give access [for repair, replacement and connection maintenance] to and from warehouse and mezzanine style industrial shelving or equivalent with flooring inserts inside said shelving, level with mezzanine and separately, by level, ground level flooring, thereby creating functional, “drawer” assemblies for said pallet-racked and dollied palletized module arrays, with drawbridge access by tier and cat walks, stairwells, elevators, etc. as necessary, incorporated by reference from patent two. External peripheral nonstandard palletized or otherwise arrayed shapes are used for support machinery such as cooling, etc. or as otherwise required for any miscellaneous purpose. Further, the approximated tessellation/tilings conjunct individual palletized arrays and stacks conjunct industrial shelving, give an industrial standard readily recognizable and easily duplicated and understood as a spatial commodity and form factor in industry, replete with pre-existing off the shelf robotic automation ready to be tasked to this new purpose. Of course standard modules may be pressed into any such service at required.

Service access for rewiring of inter-module communications is accomplished by:

-   -   1. Arranging modules in vertical linear stacks.     -   2. Utilizing cable grippers, embedded in modules, threaded on         cables, and terminated with clevis pins and clevises or         equivalently functioning hardware. Each module has three or four         such cable assemblies as exemplified in patent two Dwg. 1 Figs.         D-I as submitted and hereby incorporated by reference. Said         cable assemblies interconnect to those modules above and below,         finally terminating in the master air intake and exhaust plenums         for each pallet, below and above respectively. The cable         grippers, actuated by a handle actuator assembly on top, allow         movement up and down the accumulated cable assemblies between         terminations, by which access is gained to the sides of the         modules for external inter-module rewiring.     -   3. Individual modules have a sliding fit with adjacent modules,         and feature either a horizontal scalloped edge between keyed or         un-keyed “flats” framing apex centered cooling tube assemblies         for cables and wires fiber optics, coaxial cable, and/or a wave         guide cavity for RF and/or light guides for “open” optics and         optical data transmission.

Service access for module removal is accomplished by:

-   -   1. Slide units above and to the sides of the offending defective         unit, up their cable guides.     -   2. Seat units below on their respective stack bases, master         plenum bases or modules stacked thereon.     -   3. Disconnect clevis pins and clevises or functionally         equivalent hardware.     -   4. Connect power to new module, utilizing retraction power         chords on top of new module to power source above.     -   5. Mirror wiring or other connectivity placement on old module         to new replacement module as necessary, pending preexistent         means of connectivity.     -   6. Disconnect power from lower module, base or master plenum         base.     -   7. Slide out bad unit.     -   8. Reconnect clevis pins and clevises or equivalent hardware to         new module.

11. Thermal management includes options for internal and external cooling/refrigeration including liquid, air/gas and other solutions for installations from single units to palletized modular arrays utilizing individual coolant intake and exhaust plenums incorporated in the modules. This is incorporated by reference from patent 2. The invention employs standard industry stack-rack or pallet-rack caging of either corner or side fastening design, for palletization with pallet bolt on plywood or other pallet floor/bed for fastening master cooling plenum overlay with embedded matching terminations for module suspension cables, creating a bolt-on support bed for individual arrays. Modules are fitted together in three-dimensional arrays over this master coolant intake plenum on the pallets face. A master exhaust plenum is suspended from a pallet rack above, with an attendant end cap wiring basket cover for the top of each individual stack and provides exhaust handling for same. This includes utilization of standard large scale HVAC, air supply and shop vacuum systems on machine farms through master plenums, on both top and bottom of rollout pallet dollied and racked palletized modules, stacks and arrays in single and multi-tier industrial shelf based storage at drawers. [Reference FIG. 17A-D: Table 1 for further thermal management options.]

The module hull includes a thermally insulative impregnation or a layer internally and/or externally, hereinafter “thermal layer” for simplicity. The module hull thermal layer directs heat from the central cavity to be carried off by internal plenums, fans, cooling tubes and associated ductwork, end cap fans, master intake and exhaust plenums and arrays of the same, and/or other thermal management.

The hull is also thermally insulated with a view to human touch. To this end, the end cap wiring basket, cover and handle are also thermally insulated.

12. Module and nested sub-module design conjunct peripheral odd shape support modules allow economic trade-offs between battle hardening redundancies and green design based on [sub-]system(s) consolidation(s).

13. Extended depth stacking of modules is accomplished by rotating the electrical interconnection by module or [sub-] module through multiple electrical plug connections per module from 1 to n, where n the maximum number of power plugs per module is matched on both top and bottom for each module. Vertical module position in the stack dictates which plug daisy chain series to which that module will be connected in rotation.

14. Hot swap is accomplished by using a double-ended “closed loop” [for each conductor] bus bar. This means that for each power source there are two feeds, for which loads are daisy-chained in stacked fashion. The daisy-chained loads are fed from both top and bottom from the same source, thus forming a double-ended bus bar. If power is disconnected from one end, it is still available from the alternate powered end of the daisy chain. Further, in a pinch such wiring may be (re-)wired to alternate power sources, for damage control.

15. Unlike other patents and/or products, radiation reflective paint or impregnation is utilized to establish preferred non-isotropic directionalities and hence gain in the preferred directions, and radiation absorbent paint is used to absorb and hence retard radiation in non-preferred directionalities when light and wave guides are used on outer hull. The module hull includes thermal insulative and/or conductive layers to establish preferred heat flow patterns, covered or included in the radiation absorbing media. The module hull end basket cover and handle are RF and thermally insulated for human touch, and the thermal layer directs heat into the central cavity to be carried off by the ductwork and/or other thermal management.

16. Wiring as put forth herein extends to the interconnection of conductive paths between layers of substrate and attendant masked material deposits or subtractions in chips and/or boards envisioning the fundamental wiring layout of the modules as put forth in drawings 8A-C for layout between layers of said constructs. This includes Futjitsu's use of composite carbon nanotube-graphene conductive molecularly bonded arrays. All wiring as put forth herein and in patents incorporated by reference shall b3 e inclusive and include chip socketing as a symbolically represented in all drawings on a molecular and nanoscale and chip level.

17. Further, wiring as put forth in Dwg. 8 is extended to the atomic level by utilizing drawings 8A-C symbolically in conjunct with constructs of wires utilizing lead or other high conductivity atoms three or more or more atoms thick.

18. In all cases, the bypass feature, as posited in drawings 8 a-c allows for mono-planar and multi-planar re-configurable variable length push pull bus shortest path with optical and other direct memory link processing between the processors in single and multi-planar arrays. The key is moving between the linearly displaced first and third modules, chips or atomic circuits as delineated above.

The invention differs from already patented and/or made inventions as follows:

-   -   1. Other inventions and/or products do not use approximated         tessellation/tiling with single and multi-module redundant         wiring for failover and rerouting for battle hardening with or         without internal part layout and wiring mirroring external         geometry.     -   2. Other inventions and/or products do not use approximated         tiling/tessellation with bulk-head to bulk-head inter-module         sliding-fit contact to maximize surface area utilization for         stacks, and co- and multi-planar arrays with or without         suspension cabling.     -   3. Other inventions and/or products do not use approximated         tiling/tessellation with bulk-head to bulk-head inter-module         sliding-fit where retractable interconnection lengths are         minimized for performance gains and therefore signal, data,         propagation times, and/or process delays are minimized with         supercomputing possibilities.     -   4. Other inventions do not use approximated         tessellations/tilings with a sliding fit to maximize internal         rate of return (IRR) as measured by floor space utilization with         module footprints projected into the third dimension to         volumetrically form modules that are then stacked to form         abutting rows and/or columns and hence arrays.     -   5. Other inventions do not use approximated         tessellations/tilings with a sliding fit with master intake and         exhaust plenums used to columnarize module stacks for thermal         management in module arrays on pallets, pallet racked and         dollied to make sliding pallet drawer assemblies with fold-down         drawbridge worktables and industrial shelving with/without         mezzanine and catwalk options for buildout of old buildings and         exterior roofing and walls with insulation for new buildings.     -   6. Other inventions do not allow for sliding fit         tessellation/tiling service access and/or replacement with         (sub-)module/array palletized modules incorporating nested         sub-modules utilizing cable guided locking manual and/or         automated systems with retractable interconnects and/or quick         disconnects with positive shutoffs.     -   7. The invention unlike other inventions and/or products, does         not require direct plug to socket rigid alignment for co-planar         interconnects thus limiting inter-module co-planar and         multi-planar proximity, access, serviceability and replacement.     -   8. The invention, unlike other designs, does not use drooping         wires hung from purported tessellated hubs which have no design         reason for one shape over another and claim precedence for         shapes from a square to a circle including the standard         tessellated shapes here but give no reason for their usage.     -   9. Other inventions do not have sliding fit modules including         palletized stack rack and dollied modules with coolant intake         and exhaust master arrays of master plenums with central end cap         cooling or plenums, both with fans, ductwork and peripheral         module cooling hose assemblies and with internal and external         cooling options.     -   10. Other inventions do not have sliding fit modules and nested         modules based on approximated tessellations and/or tilings with         wire/cable/hose guides and interconnects conjunct quick         disconnects including positive shutoffs as necessary and cable         guide suspension/cable gripper positioning with black box design         with economic trade-offs between battle-hard redundancies and         green design based on (sub-)system(s) consolidation.     -   11. Other inventions do not allow extended depth module stacking         based on multiple feed-through module power sources with         rotating module connections based on module stack depth.     -   12. Other inventions do not use multiple double-ended         daisy-chained single power source bus bars for hot swap,         terminated with two separate feeds from the same source at         either end, through which, for multiple feeds, power is rotated         as a function of stack depth.     -   13. Other inventions do not utilizes wave guides, coaxial         cables, twisted pair, fiber optics or any other media, known or         to be contemplated, to enforce gain in preferred         directionalities with splitters as necessary, with inter-modular         and nested intra-modular inter-sub-modular sliding interface of         compensating gaskets and or coatings between inter-modular         surface interfaces as necessary for directed and constrained         traffic. This enables traffic data rates far above isotropic RF         broadcast. Other patented and/or manufactured products use         non-cabled RF or other open optics, which may be subject to         contamination by dust. Non-plug based optical alignment systems         are also used with obvious alignment issues. Omni-directional or         isotropic RF broadcast systems without wave-guide type         structures are unconstrained, and with the exception of global         commands such as startup, shut down, reset and command         look-ahead functions are not the preferred embodiment, due to         potential bandwidth contention of large numbers of modules,         particularly when data and command communications are         aggregated, unless they are constrained non-isotropically by         radiation-reflective and absorbing materials establishing gains         in preferred command, communication and control directions and         retarding same in other directions with or without key ways on         hull inter- and intra-module interfaces.

Said drawings and their attendant FIGS. (1-16) are enumerated as follows:

-   -   1. Palletization: Bottom Release Enclosure: Full Assembly         -   A. Top View, Six Sided Asteroid         -   B. Symmetrical Handle: Top View         -   C. Side View: Sight top to left of sheet.         -   D. Optional Triangular Variant less handle         -   E. Symbolic Build-Out from Single Equilateral Triangle

Structure to Hexagon, Square and Fractal Larger Equilateral Triangle with Implicit Nesting and Array.

-   -   -   F. Example Triangle Used To Complete a Square peripherally             or other wise.         -   G. Square Approximating Tesselation/Tiling Tile.         -   H. Symbolic Build-Out Using Square or Octagonal

Approximations as Representative Tile/Tesselations Appro with symbolic Array Representation.

-   -   -   I. Hexagonal Variation

    -   2. Palletization: Top Release Enclosure:         -   A. Full Assembly, Top View;         -   B. Symmetrical Handle: Top View;         -   C. Side View: [Sight top to left of sheet].

    -   3. Palletization: Enclosure-base and Exhaust Plenum Matrix Array         Subset Layout Pattern:         -   A. Top View         -   B. Inter-modular Interface Surface Finish and Sculpting             -   Note: Two Inter-Modular Surfaces, As Shown, Make A Guide                 When Openly Facing Each Other, Types are as Follows:             -   10. Module Type One or Two, Top View.             -   20. Intake Master Plenum, Top View.             -   30. Exhaust Master Plenum, Top View             -   40. Wire/Cable/Tube/etc. Guide(s)             -   50. RF Wave Guide(s)//Splitter(s) [example: three shown]             -   60. Light Guide(s)/Splitters [example: three shown]             -   70. Blank Flats             -   80. Both Sides Of A—One Assy.             -   90. Both Sides Of B—One Assy.             -   100. Both Sides Of C—One Assy.             -   110. Any One of (E-G) In Combination With An Outward                 Face (A-D) Thereof

    -   4. Palletization: Scalable Single Base for Enclosure Types 1, 2         & 3, Respectively, All Top or Bottom Release Enclosure Styles:         -   A. Base: Connector Bay: Top View         -   B. Base: Connector Bay: Internal Perspective View         -   C. Base: Connector Bay: Side View         -   D. Base: Wiring/Coolant Master Plenum Sub-Assembly: Side             View         -   E. base: Wiring/Coolant Connector Bay Master Assembly Wiring             Basket         -   F. Base: Wiring/Coolant Master Plenum Hose Assembly Quarter             Turn Locking Mechanism and Seats Panel Sub-Assembly:             Internal Perspective View         -   G. Base: Wiring/Coolant Master Plenum Feed through             Sub-Assembly: Internal Perspective View.         -   H. Base: Connector Bay and Wiring/Coolant Master Plenum             Sub-Assembly: Side View.         -   I. Base: Full Assembly: Side View.

    -   5. Palletization: Scalable Single Exhaust Plenum Cap,         Wiring/Cable/Plumbing [Coolant, Gravity Feed, pumped, etc.]         Connector Bay and Cable Hanger Assembly: For Top or Bottom         Release Enclosure [Symmetrical @120 Degrees]         -   A. Cap: Wiring/Coolant Master Plenum Sub-Assembly: Top View         -   B. Cap: Wiring/Coolant Master Plenum Sub-Assembly: Internal             Perspective Side View         -   C. Cap: Wiring/Coolant Master Plenum Sub-Assembly: Side View         -   D. Cap: Connector Bay Cover: Bottom View         -   E. Cap: Connector Bay Cover Wiring Basket Feed Through             Panel: Internal Perspective View         -   F. Cap: Connector Bay Cover Hose Assembly Quarter Turn Locks             and Seat: Side View         -   G. Cap: Connector Bay Cover Sub-Assembly: Side View         -   H. Cap: Connector Bay Cover and Wiring/Coolant Master Plenum             Full Assembly: Side View

    -   6. Palletization: Base And Cap Cable Hanger Assembly Scalable         Single Base: For Top or Bottom Release Enclosure, Connector Bay         -   A. Hanger Assembly: Perspective View             -   158. Outer Collar             -   159. Pin             -   161. Clevis             -   160. Tubular Bearing Surface             -   162. Cotter Pin             -   163. Optional Heavy Load Gusset             -   164. Plenum Intake/Exhaust Hull             -   165. Inner Collar             -   166. Hexagon Socket Set Screw With Flat Point             -   167. Cable             -   168. Cable Termination Hook

    -   7. Palletization: Enclosure Type 1, 2 or 3 Base Unit 2D Matrix         Array Stacking         -   A. Stacking Sequence; Base Plus modules         -   B. Single Stack         -   C. Stack Array

    -   8. Palletization: Single Plane Radial and Symmetrical         Inter-Modular Matrices         -   A. Module Centric Single Plane Inter-Module Array         -   B. Single Plane Symmetrical Inter-Module Matrix         -   C. Asterisk Shape Overlaid on a 3×3 Module Array         -   D. Single Leg Variable Length Spark Resistant Ball and             Slotted Socket Electrical Connector             -   200 Slotted Ball Socket Cover             -   203 Self Tapping Screw Seat             -   205 Ball Socket Cover             -   210 Ball Socket Seat             -   213 Self Tapping Screw Seat             -   215 Ball Socket Seat             -   217 Self Tapping Screw             -   220 Ball             -   222 Allen Head Socket             -   224 Ball Neck             -   226 Threaded Cap [Spark Resistant: Bronze, etc.]             -   230 Cartridge [Spark Resistant: Bronze, etc.]             -   232 Cotter Pin             -   234 Shoulder Washer [Spark Resistant: Bronze, etc.]             -   236 Open End Cartridge Thread             -   240 Plunger [Spark Resistant: Bronze, etc.]             -   242 Spring Retention Hole             -   244 Carbon impregnated material or coating.             -   246 Cable Receiver             -   250 Cable [Optional: Spark Resistant: Impregnated Carbon                 or Other Similar Material etc.]             -   260 Contracting Spring

    -   9. Palletization: Master Air Intake Plenum         -   A. Top View         -   B. Bottom View         -   C. Side View             -   400. Air Intake Hole Knock Outs             -   410. Suspension Alignment Hook         -   D. Front View             -   400. Air Intake Hole Knock Outs         -   E. Master Air Intake Plenum With Parting Lines             -   420. O-Ring Material Extruded Seals

    -   10. Palletization: Master Pallet Air Exhaust Plenum         -   A. Top View         -   B. Bottom View             -   430. Pallet Rack Cross Bars         -   C. Side View             -   400. Air Intake Hole Knock Outs         -   D. Front View             -   400. Air Intake Hole Knock Outs             -   410. Suspension Alignment Hook         -   E. Master Air Intake Plenum With Parting Lines             -   420. O-Ring Material Extruded Seals

    -   11. Palletization: Stackable Warehouse Pallet with Master Intake         and Exhaust Plenums Installed         -   A. Blank Pallet With Pallet Rack [Corner Mount Shown, Side             Mount Obvious]         -   B. [Bottom] Master Intake, [Top] Master Exhaust Plenums         -   C. Palletized Master Plenums Installed

    -   12. Palletization: Palletized and Dollied “Sliding Drawer”         Master Cooling Array Assembly         -   450. Pallet Dolly

    -   13. Palletization: Master Cooling Assembly Population         -   A. Module Base Stacked Order         -   B. Single Stack Assembly         -   C. Stack Array         -   D. Palletized And Dollied Master Cooling Assembly Being             Populated With Modules

    -   14. Palletization: Dolly Shelf Bed and Supports, Slotted Cable         Guide and Conduit Whip         -   A. Shelf Bed             -   500. Pallet Dolly Load Bearing Surface         -   B. Castellated Cross Brace With             -   510. Stud Eye Mounts             -   515. Castellated Cross Brace             -   517. Top Center Cable Guide         -   C. Slotted Support Beams         -   D. Central Longitudinally Slotted Cable Guide Shelf Base             Assembly         -   E. 180 Degree Arc Cable Conduit Whip             -   508. Internally Threaded Flange             -   510. Stud Eye Mounts             -   520. 90 Degree Bend Electrical Conduit         -   F. Industrial Warehouse Mezzanine Shelving

    -   15. Palletization: Scalable Computer/Router Farm Utilizing         Standard [Catalog] Industrial Warehouse Shelving with Mezzanine         Option above Single Floor Installations for Pre-Existent         Warehouse Space Build out and New Construction [Catalog] Steel         Building with Integrated Industrial Walls and Roofing         -   A. Modular Stack [Top and Bottom Arrows Represent Data             Connections: Cables/Wires/Ethernet/Fiber Optic/etc.]         -   B. Dollied Stack Racked Pallet(s) With Installed Intake             [Bottom]/Exhaust [Top] Coolant/Wiring/Stack Suspension             Master Plenums         -   C. Symbolic Standard Industrial Warehouse Shelving For             Population By Dollied And Palletized Modules

    -   16. Palletization: Shelf Level Drawbridge Assembly         -   A. Drawbridge [Top, Side and End Views]             -   540. Drawbridge Deck         -   B. Drawbridge Hinge             -   517. Wire Guide             -   530. Pivot Rod         -   C. Drawbridge Symmetrical Pivot Rod [Side And End Views]             -   510. Stud Eye Mount             -   530. Pivot Rod         -   D. Shelving Top View [Symbolic]:             -   540. Full Drawbridge Assembly Installed             -   530. Hinge With Pivot Rod Only             -   535. Industrial Shelving: Two Second-Tier Single Bays                 Facing Each Other Separated By A Walk Way.         -   E. Shelving Front View [Symbolic]             -   530. Hinge With Pivot Rod Only             -   535. Full Drawbridge Assembly Installed

The parts of my invention and how they relate to each other follow:

Patent application Ser. No. 12/806,211 is incorporated by reference.

Dwg. 1 shows Module Type 1 from patent application Ser. No. 12/806,211 incorporated by reference.

Dwg. 2 shows Module Type 2 from patent application Ser. No. 12/806,211 incorporated by reference.

Dwg. 3 shows a top view conjoining multiple modules [part 10], with an unpopulated intake plenum [part 20] and populated exhaust plenum [part 30].

FIG. 3B part 60 shows inter-modular interface surface finish and sculpting. Two such surfaces in inter-modular contact as shown, make wire guides as listed in the drawings' figure descriptions.

FIG. 3B parts 40 and 50 show single/multi-cavity inter-modular surfaces Making up a guide, with a central cavity, when matched to an abutting module with landings and sliding EMI/RFI O-gasketry while end caps complete such cavities with appropriate access mounts and gasketry, pending technology employed, as shown symbolically in parts 80-100 on each horizontal face or mix and match is possible.

Inter-module interface sides must be recessed the width of the full cavity enclosures plus the tolerance for a sliding fit. This recess with or without keys and keyways must have landings and stops for guide retention. Bottom stops must have matching top/stops on abutting modules.

Combo Units are allowed and are shown symbolically as parts 110-130 with outward faces 40-70.

Parts 40-130 in the preferred embodiment are made out of solid metal and/or absorptive/coating with reflective coating overlay and/or gasketry. Gasketry includes Mu-metal, EMI field conductive material [copper, iron, carbon, silver, gold, nickel, beryllium copper, impregnated gel/silicone, o-rings, mesh, etc. Outlying or abutting areas and/or the remainder of adjoining internal or external areas are coated with applicable radiation/energy absorbing materials as necessary, obviating the necessity of a full seal in some instances, while allowing looser tolerances in a sliding fit without cross-talk or other interference from nearby or neighboring guides.

Actual geometry may vary pending frequency, energy, collimation, polarization and/or propagation mode(s) and includes standard and/or special-order catalog and/or by design items.

Cables used in such embodiments must not be conductive for the energy spectrum and/or radiation characteristics to be used.

Dwg. 4 shows an individual male base upon which a type 1, 2 or 3 module may be seated.

In the preferred embodiment, the area between the outside of the three (3) individual intake ducts, where the ducts' curve as they slope down toward the fan intakes is the area for pass through wiring, cabling, plumbing, and other standard and common non-thermal management connections, etc.

Seals may be upgraded to be hermetic, explosion-proof and/or degassed pending usage.

Dwg. 5 Shows a single of wiring basket cover exhaust plenum cap.

In the preferred embodiment, the area abutting the outside of the plenum's three (3) individual intake ducts, where the ducts' curve as they slope down toward the fan intakes is the area for pass-through wiring, cabling, plumbing, and other non-thermal management connections, etc.

Seals may be upgraded to be hermetic, explosion-proof and/or degassed pending usage.

Dwg. 6. shows a module hanger assembly, incorporated by reference from patent two as used in top and bottom master exhaust and intake plenums with cable assemblies for stack alignment in palletized module arrays.

Dwg. 7 FIG. 7 shows hanger assemblies for type 1, 2 or 3 modules. FIG. 7A shows the alignment of a base unit, and two modules. FIG. 7B shows two modules stacked on a base. FIG. 7C shows single stack assemblies further aggregated into a row array.

FIG. 8A shows the symbolic visual interrelations of a single module-centric view in a single plane to other modules in an inter-module array with possible triangular slip-fit internal module nesting. This may be utilized for centralized array master-slave command and control.

FIG. 8B shows the symbolic visual inter-module relations without the central module command and control view, however with possible nesting. However, the interconnectivity embodied herein, incorporates by reference as the patents one and two, as the concept is extended to multiple planes.

Both FIGS. 8A and 8B utilize the following legend:

Heavy line: Used for router/computer or other connection.

Light line: Used for router/computer or other connection.

Dashed line: Used for router/computer or other connection.

Fill: Not used or used for cooling machinery or other support equipment.

FIG. 8C Six pointed Star Overlaid on a 3×3 Array. Symbolically demonstrates module vertical cut cross-section data, process, control and/or other information transport or combination thereof either vertically, horizontally or diagonally across EACH symmetrical module, set of modules or other geometric shape or shapes with or without single or multiple central unit bypass for rerouting, multi- or parallel processing or failover. This symbolic side view when read in relation to a top center view as shown in FIG. 8A shows symbolically, without recounting sides allows six sides each for horizontal and vertical planes, not including the central unit. Symbolically these views also represent cross-sections of multi-layer substrates when so extended as symbolic representations of duplex, multi-duplex parallel [bypass] and single directional busses, regular and irregular triangular, square, hexagonal, octagonal shapes with or without the dumbbell variant as claimed. This is further extended to the atomic basis as put forth here by using lead wire or other conductive material three or more atoms thick with amperage rating to 10 amps.

FIG. 8D is a Single Cable Self Adjusting Variable Length Connector with Anti-Spark Explosion Proof Option. These units are mounted on the external side wall recesses between vertically abutting [intra-planar] and diagonally adjacent inter-planar adjacent modules to allow motion and communication. Multiple units are required to complete circuit, +, − and ground. All other forms of interconnect are allowed as illustrated elsewhere in this document. The author holds that parts 200-246 as listed above are self-explanatory in function, however for simplicity, parts 200-226 describe a ball and socket mechanism. Part 230 acts as a cartridge based retention system for the contracting spring [part 260] and plunger [parts 240-246]. Two such units are connected by a cable [250]. The total assembly creates a variable length conductive path. The path is made spark resistant by the strategic use of bronze and carbon impregnated components or equivalent for spark resistance.

Dwg. 9 shows a Master Intake Palletized Plenum Array designed to work with various heat transfer mechanisms as indicated, as referenced, but not limited to, FIG. 17A-D: Table 1, to feed coolant through such bases, which comprise its assembly, or through direct connection to module central cavities as required. Seals are provided for said plenums and vertical suspension alignment hooks, three per module, are utilized for alignment tethers for inter-module cable assemblies. This allows for module, replacement with possible hot-swap pending internal and external component selection and external rewiring,

Dwg. 10 shows the master air exhaust plenum, upper termination hooks, three per module, in alignment with one-to-one correspondence with the suspension alignment hooks of the master air intake plenum with the same sealing system of Dwg. 9.

Dwg. 11 shows a blank pallet with corner-mount pallet rack installed, side mount, although not shown, should be blatantly obvious to those versed in the art. [Bottom] master intake, and [top] master exhaust plenums are next shown installed.

Dwg. 12 shows a palletized “sliding drawer” assembly constituted by addition of a pallet dolly with wheels or rollers set offside of the center cable gutter pending size, weight load and economic requirements.

Dwg. 13. FIG. 13A shows the stacking alignment of modules on a base. FIG. 13B shows the assembly of said modules into a single stack. FIG. 13C shows the assembly of single stacks and stacks arrays. FIG. 13D shows the stack arrays being populated into the palletized and dollied master cooling/wiring/stack suspension assemblies.

Dwg. 14 shows the shelf support structure for stored, dollied and palletized module arrays with an external wire guide armature to prevent entanglement of pallet wiring connections when rolling out the palletized dolly from its shelf bay for work.

The FIG. 14E Assembly may be left or right mounted on part 515 of FIG. 14B. This assembly with part 517 prevents jamming of cables, when dollied palette is in motion.

Dwg. 15 shows the scalable computer/router farm, utilizing standard warehouse shelving with mezzanine option above single floor installations for pre-existent warehouse space build out and new construction steel building with integrated industrial walls and roofing.

Dwg. 16 shows a drawbridge arrangement for bin height dollied and palletized module array extraction from second-tier and above multi-tier industrial shelving bins onto the fold-down flat work area provided for by said “draw bridge” for service, replacement, etc. The minimalist embodiment comprises two base shelving units with appropriate sized dollied, palletized and pallet-racked modules with master plenums separated by an appropriate number of drawbridges sized for the selected pallet shelf combination shared by the pallets of each base shelf, allowing full-motion and access to all dollied pallets and modules.

Dwg. 17 symbolically references flow charts of probable cooling schema and as such are self-explanatory as expressed in FIG. 17A-D, Table 1. 

1. The preferred embodiment and methods claim approximated tessellation with redundant wiring for routing, fail over, and rerouting of data, feedback and command and control of computers, bus based systems, to include the utilization of integrated circuits and hybrids with or without biotech, memory, networks, machinery and machine farms, and processes with or without feed back or signaling.
 2. The preferred embodiment and methods claim approximated tessellation with sidewall bulkhead to sidewall bulkhead inter-module sliding fit contact to maximize surface aqrea utilization for stacks as measured by footprint, and co- and multi-planar arrays with or without suspension cabling.
 3. The preferred embodiment and methods claim scalable integration/migration from a single unit to a massively parallel router, server, supercomputer(s) and process-based machine farms trough data and command path length reduction and standardization and inter- and intra-module bypass for massive parallel processing.
 4. The preferred embodiment and methods claim an almost universal form factor with sub-module sliding fit.
 5. The preferred embodiment and methods claim approximated tessellated and/or tiled modules, with inter-module sliding fit, nested ins single and multi-tiered shelving, industrial or otherwise, utilizing dallied and pallet racked pallets as slide out drawers with foldout drawbridge workspaces for support when in the out position, with or without mezzanines and catwalks for old building build-outs and externally facing roofs and walls and separately elevators of new construction.
 6. The preferred embodiment and methods claim ad hoc nested or un-nested (sub-)module access in stack and/or co- and/or multi-planar array service, repair, updating, (re-)wiring, (re-)cabling, (re-)piping, or (re-) placement or other modification with or without manual and/or automated access.
 7. The preferred embodiment and methods claim thermal management, including module insulation of stacked and arrayed nested and un-nested modules and sub-modules in drawers mode of dollied and pallet racked pallets with individual stacks utilizing master intake and exhaust plenums seated in arrays on top of each pallet and at the bottom of each pallet rack, seated in standard industrial shelving with fold down and multi-tier, industrial draw bridge work areas.
 8. Alternate embodiments and methods claimed non-exclusively top and bottom intake and/or exhaust end caps, fan guard screens and fans internal plenums, associated fans and peripheral module cooling hose assemblies, HVAC, shop blowers and other internal and external cooling options as referenced in FIG. 17A-D Table
 1. 9. The preferred embodiment and methods claim module and sub-module nested design for “black box” for battle hard redundancies.
 10. An alternate preferred embodiment and methods claim module and sub-module nested design for “black box” for green design by systems consolidation of systems redundancies.
 11. The preferred embodiment and methods claim hot swap based on multiple double ended daisy chained single power source bus bars terminated with two separate feeds from the same source at either end, which for the number of such feeds, power is drawn for a particular module in rotation.
 12. The preferred non-exclusive embodiment and methods claim a multi-module sliding fit interface with surface “wave guides” with radiation reflective material for preferred directionalities and absorbent coatings for non-preferred directionalities when open wave guides are used on the outer hull. Coatings may be internal or external to the hull.
 13. In an alternate non-exclusive embodiment the hull incorporates conductive material and or insulative material and/or absorptive material at the radiative frequencies or thermal bands required as either a composite within the hull material.
 14. The module hull, handle and basket covers are RF and thermally insulated to human touch and the thermal layer directs heat from the central cavity through specific systems such as ductwork and/or thermal management.
 15. The preferred embodiment and methods claim inter- and intra-module wiring including bypass for optical, electric or any other form of radiation for process control, feedback, data bus signal processing and/or other communication of one or more module corollaries based on regular and/or irregular approximated tessellated shapes with or without dumbbell modification as extrapolated into the chip level, based on multi-layered substrates and the addition and/or subtraction of material by whatever means.
 16. The preferred embodiment and methods claim atomic level wiring whereby lead, three atoms thick or other conductive equivalent media so wired in the same fashion as in the chip level mentioned above in relation to dwg. 8A-C or any subset thereof as single or multi-planar interconnected arrays of optical or any other form of radiation for process control, feedback, data, including bus, signal processing and/or other communication.
 17. The preferred embodiment and methods claim wiring as put forth herein which extends to the interconnection of conductive paths between layers of substrate and attendant masked material deposits or subtractions in chips and/or boards envisioning the fundamental wiring layout of the modules as put forth in drawings 8A-C of layout between layers of said constructs.
 18. The preferred embodiment and methods claim wiring as put forth in Dwg. 8 as extended to the atomic level by utilizing drawings 8A-C symbolically in conjunct with constructs of wires utilizing lead three or more atoms thick.
 19. The preferred embodiment and methods claim the bypass feature as described in drawings 8A-C which allows for mono-planar and multi-planar re-configurable critical path variable length push-pull (feed the nearest neighbor processor with feedback, either linear, circular bus, circuitous or meandering shortest path bus with optical and other direct memory link processing between the processors in single and multi-planar arrays. The key is moving between the linearly displaced first and n+ modules, chips or atomic circuits as delineated above. As numbers may only be used for part of the drawing numbers and letters may only be used for multiple figures there does not appear to be a nomenclature for 1,3 . . . N or M,N . . . O where M is the start point and N is the step and O is the termination which is meant here in FIG. 8C. I ask for such an indulgence [USPTO help desk telcon references 1-154902367 and 1555341101] meaning a skip in connectivity from 1 to another linear point in the array based on Cartesian [2D planar{tilde over ( )}square] 3D planar [hexagon], 4D planar [octagon] or apex truncated and rounded equivalents of these forms with or without dumbbell equivalents. The preferred embodiment is then the Fibonacci series (1/1, 2/1, 3/2, 8/5, 13/8, 21/13 . . . or interconnection starts and subsequent interconnection skips 1,1,2,3,5,8,13,21,39,60,99,159,258 . . . N projected as an interconnect adjunct onto these geometries. This makes a series of program controlled concatenatable variable length push pull bus(es) with the push-pull or skip features connecting modules bypassing the primary path, while said modules are directly connected to the primary path. There are multiple processing models here, a further model utilizes concentric processor rings as shown and starts with a singular central hub processor, routers, etc surrounded by six of same which expands out as a standard progression shown ring after ring. Multiple singular planes of rings are then projected by stacking in array fashion to multiple planes. Data is the passed between rings and planes and hubs for processing in extensible push-pull bus fashion. Push-pull is herein defined as passing data to a contiguous processor whereby it runs down a variable length tree with as many leaves as necessary and returns task as fulfilled using all contiguous processors and/or groups of processors as necessary to the critical path as necessary. 